. "Satellite geodesy"@en . . "4" . "Lecture: the theory of the motion of artificial satellites: Keplerian and perturbed motion; Kepler's laws; elements of the orbit; types of orbits; equation of motion; integration of equations of motion;\nmovement in circular and elliptical orbits; Kepler's equation; orbital and geocentric coordinates of the satellites; elements of a circular orbit; satellites ground track; geostationary satellite and its\napplications; perturbed satellite motion; classification of perturbing forces; osculatory elements; secular, long-term, short-term and diurnal perturbations; perturbations caused by the eccentric\ngravitational field and the atmospheric effect. Techniques of artificial satellites observation: classification of observation techniques; principles of the satellite laser ranging (SLR), altimetric and\ngradiometric measurements; basic information about photographic and Doppler techniques. GNSS measurements: the architecture of GNSS systems; GNSS satellite signal structure; receivers and\nantennas; code and carrier-phase method of measuring the distance to a satellite. Initialization problem in GNSS measurements; absolute and relative methods. GNSS measurement technologies: static,\nfast static, kinematic, RTK/NRTK and DGNSS; GNSS measurement errors; the differencing of GPS observation (single-, double, triple difference), linear combinations of the carrier-phase observations\nand their applicability and their advantages and disadvantages. Other existing and planned global satellite navigation systems: GLONASS, Compass and Galileo systems; system similarities and\ndifferences; the benefits of using them together. Overview of regional satellite navigation systems: EGNOS, QZSS, IRNSS GAGAN etc. Satellite and Ground Augmentation Systems, national augmentation\nsystem ASG-EUPOS. A brief overview of currently operating satellite missions (DORIS, GOCE, CHAMP, GRACE). Laboratory: the theory of the artificial satellite motion; determination of horizontal\ncoordinates of a geostationary satellite; determination of the geocentric coordinates of the GPS satellite based on the broadcast ephemeris; calculation of DOP parameters; planning and field\nmeasurement with the use of static and fast static technology; GNSS data processing - vector determination and GNSS network adjustment; quality evaluation of the results; preparation and field\nmeasurement with the use RTK/NRTK technology; ASG-EUPOS services - rules of use and data formats" . . "Presential"@en . "TRUE" . . "Geodesy"@en . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . "Bachelor in Geodesy and Cartography"@en . . "https://www.gik.pw.edu.pl/gik_en/Studies" . "209"^^ . "Presential"@en . "Geodesy is historically the science of surveying the Earth and presenting its image in the form of maps related to cartography. Modern geodesy and cartography is still the field of science related to surveying, but with the use of many observational techniques starting with geodesy and geodynamics through satellite and airborne photogrammetric imaging, remote sensing techniques to classic ground-based surveying and legal aspects of cadastral and property management. The variety of Earth observation techniques is constantly increasing the role of a surveyors and cartographers as those who can integrate all these data, providing precise spatial location and georeferenced and is able to present and interpret occurring phenomena."@en . . . . "3.5"@en . "TRUE" . . . "Bachelor"@en . "Both" . "Not informative" . "Euro"@en . "Not informative" . "Mandatory" . "no data"@en . "7"^^ . "TRUE" . "Downstream"@en . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .